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This course involves a series of lectures on applying the process of engineering design. Students will learn to develop their ability in design while completing two design assignments. The first assignment involves a conceptual design task. This task description will be vague and incompletely specified. Students will gather and critically assess information required to clarify the task. During the process of conceptual design students will create alternative design solutions. These solutions will be evaluated and the most suitable design concept selected and developed. The second assignment involves an embodiment and detail design task. Students will start with an engineering concept and will evolve this concept towards a detailed technical system in which performance, reliability and economy are maximised. These objectives are achieved under the umbrella of two overriding objectives, namely, safety and sustainability.
Sample of lecture topics:Design Process; Context of Design; Clarification of the Task; Conceptual Design; Safety; Materials Selection in Mechanical Design; Embodiment Design; Structural Design of Machine Elements; Gearbox Design; Hydraulic System Design; Detail Design; Design analysis methods.
Learning Outcomes and National Qualifications Framework (NQF)Knowledge outcomes:To understand the principles and practice of engineering designTo understand design in the context of the wider organisation Skills outcomes:To define the engineering task, given a generally and incompletely specified need;To gather and critically assess information required to clarify the task and support conceptual design;To create alternative conceptual design solutions;To evaluate concept choices and decide on the most suitable design concept; to carry out embodiment and detail design of mechanical systems;To communicate the design in drawing and written report form. To be able to synthesise an engineering system design, drawing on acquired knowledge in engineering sciences, technology and engineering economics.To be able to carry out design in a context of social responsibility, and with due awareness of safety, legal and commercial requirements.To be proficient in the use of CAD and mathematical tools for engineering analysis.To integrate design with the manufacturing processes.To be able to design effectively in a new and unfamiliar area.To become competent in applying the process of engineering design.Personal attributes developed:To be able to present a clear and competent description (written or oral) of a component or system design to either a technical or non-technical audience.To be able to recognise one’s personal limits of design competence and when to seek more expert advice.
ENME311 or ENMT301
ENME440
Shayne Gooch
Hales, Crispin , Gooch, Shayne; Managing engineering design ; 2nd ed; Springer, 2004.
Adams, James L; Conceptual blockbusting : a guide to better ideas ; 3rd ed.; Addison-Wesley, 1986.
Ashby, M. F; Materials selection in mechanical design ; 2nd ed; Butterworth-Heinemann, 1999.
Deutschman, Aaron D. , Michels, Walter J., Wilson, Charles E; Machine design : theory and practice ; Macmillan, 1975.
Dieter, George Ellwood; Engineering design : a materials and processing approach ; 3rd ed; McGraw-Hill, 2000.
Johnson, Ray C; Optimum design of mechanical elements ; 2nd ed; Wiley, 1980.
Pahl, G. , Wallace, Ken., Blessing, Lucienne; Engineering design : a systematic approach ; 3rd ed; Springer, 2007.
Pugh, Stuart; Total design : integrated methods for successful product engineering ; Addison-Wesley Pub. Co, 1991.
Shigley, J.E.,; Mechanical Engineering Design ; 1st Metric Edition; McGraw Hill, 2007.
Ulrich, Karl T. , Eppinger, Steven D; Product design and development ; 2nd ed; Irwin/McGraw-Hill, 2000.
Domestic fee $1,018.00
International fee $4,863.00
* All fees are inclusive of NZ GST or any equivalent overseas tax, and do not include any programme level discount or additional course-related expenses.
For further information see Mechanical Engineering .